Electronic circuit, module, and system

ABSTRACT

A convenient electronic circuit in which a switch is able to be switched through electric power obtained using weak radio waves is provided. An electronic circuit includes a switch which is connected between a power supply configured to output direct current (DC) electric power and a load driven through DC electric power supplied from the power supply and which switches a connection state between the power supply and the load from a non-conduction state to a conduction state; a power conversion circuit which includes a power input terminal to which electric power obtained through radio waves received by an antenna is input and a DC power output terminal configured to output DC electric power and which converts electric power input to the power input terminal into DC electric power and outputs the converted DC electric power from the DC power output terminal; and a control circuit configured to control a connection state of the switch to be in a conduction state when the power conversion circuit outputs DC electric power. The power conversion circuit includes at least a first capacitor, a first diode, a second capacitor, and a second diode.

RELATED APPLICATIONS

This application claims priority to Japanese Patent Application No.2020-036248, filed on Mar. 3, 2020, the entire content of which isincorporated herein by reference.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to an electronic circuit, a module, and asystem.

2. Description of the Related Art

In the related art, in electronic keys used for key systems forvehicles, electronic keys communicate with the vehicles when batteriesbuilt into the electronic keys are connected to control circuits usingthe electric power obtained using the radio waves from the vehicles.Techniques for minimizing the consumption of batteries in a standbystate by cutting off the connection between batteries and circuits againif electronic keys are distant from vehicles (that is, during standby)are known (for example, refer to Patent Document 1)

PATENT DOCUMENTS

[Patent Document 1] Japanese Unexamined Patent Application, FirstPublication No. 2011-24332

SUMMARY OF THE INVENTION

In the related art as described above, an analog front-end circuit (AFE)inside an electronic key is started up using electric power obtained byradio waves from a vehicle. At this time, the AFE is started up usingelectric power obtained by radio waves from a specific apparatusprovided in the vehicle or the like.

However, when the AFE is tried to be started up using radio waves fromthe vehicle, the electronic key has a problem that it takes time tostore electric power required for starting up the AFE. That is to say,it is inconvenient to have to keep the electronic key close to aposition in which the electronic key can receive radio waves from thevehicle until the electronic key is started up.

The present invention was made in view of such circumstances, and anobject of the present invention is to provide a convenient electroniccircuit in which a switch can be switched using electric power obtainedby weak radio waves.

An electronic circuit according to an aspect of the present inventionincludes a switch which is connected between a power supply configuredto output direct current (DC) electric power and a load driven throughDC electric power supplied from the power supply and which switches aconnection state between the power supply and the load from anon-conduction state in which the supply of electric power from thepower supply to the load is cut off to a conduction state in whichelectric power is supplied from the power supply to the load; a powerconversion circuit which includes a power input terminal to whichelectric power obtained through radio waves received by an antennacapable of receiving radio waves is input and a DC power output terminalconfigured to output DC electric power and which converts electric powerinput to the power input terminal into DC electric power and outputs theconverted DC electric power from the DC power output terminal; and acontrol circuit which includes an input terminal connected to the DCpower output terminal of the power conversion circuit and an outputterminal connected to the switch and configured to control a connectionstate of the switch and controls the connection state of the switch suchthat it is in a conduction state when the power conversion circuitoutputs DC electric power due to the reception of radio waves by theantenna, wherein the power conversion circuit includes at least a firstcapacitor including a first electrode and a second electrode connectedto the power input terminal, a first diode having an anode connected toa ground point and a cathode connected to the second electrode of thefirst capacitor, a second capacitor including a first electrodeconnected to the DC power output terminal and a second electrodeconnected to a ground point, and a second diode having an anodeconnected to the input terminal via a capacitor and a cathode connectedto a first electrode of the second capacitor.

In an electronic circuit according to an aspect of the presentinvention, the power conversion circuit may further include a thirdcapacitor including a first electrode and a second electrode connectedto a ground point; a third diode having an anode connected to a secondelectrode of the first capacitor and a cathode connected to the firstelectrode of the third capacitor; a fourth capacitor including a firstelectrode and a second electrode connected to the power input terminal;and a fourth diode having an anode connected to a connection pointbetween the first electrode of the third capacitor and the cathode ofthe third diode and a cathode connected to the second electrode of thefourth capacitor.

In an electronic circuit according to an aspect of the presentinvention, the power conversion circuit may further include; a fifthcapacitor including a first electrode and a second electrode connectedto a ground point; a fifth diode having an anode connected to the secondelectrode of the fourth capacitor and a cathode connected to the firstelectrode of the fifth capacitor; a sixth capacitor including a firstelectrode and a second electrode connected to the power input terminal;and a sixth diode having an anode connected to a connection pointbetween the first electrode of the fifth capacitor and the cathode ofthe fifth diode and a cathode connected to the second electrode of thesixth capacitor.

Also, a module according to an aspect of the present invention includes:the electronic circuit described above; a power supply configured tooutput DC electric power; and a load driven through DC electric powersupplied from the power supply.

A module according to an aspect of the present invention is accommodatedin a waterproof housing.

Furthermore, a system according to an aspect of the present inventionincludes the module; and a transmitter configured to transmit prescribedradio waves to the module.

According to the present invention, it is possible to provide aconvenient electronic circuit in which a switch can be switched usingelectric power obtained by weak radio waves.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating an example of a constitution of a latchsystem in an embodiment.

FIG. 2 is a diagram illustrating an example of a constitution of a latchmodule in a first embodiment.

FIG. 3 is a diagram illustrating a first modified example of theconstitution of the latch module in the first embodiment.

FIG. 4 is a diagram illustrating an example of a constitution of acontrol circuit in the first embodiment.

FIG. 5 is a diagram illustrating a second modified example of theconstitution of the latch module in the first embodiment.

FIG. 6 is a diagram illustrating an example of a housing with awaterproof structure in the first embodiment.

FIG. 7 is a diagram illustrating an example of a power conversioncircuit in a second embodiment.

FIG. 8 is a diagram illustrating a first modified example of the powerconversion circuit in the second embodiment.

FIG. 9 is a diagram illustrating a second modified example of the powerconversion circuit in the second embodiment.

FIG. 10 is a diagram illustrating an example of a first antenna and asecond antenna in a third embodiment.

FIG. 11 is a diagram illustrating an example of the first antenna andthe second antenna in a third embodiment.

FIG. 12 is a diagram illustrating an example of a constitution of alatch module in the third embodiment.

FIG. 13 is a diagram illustrating a first modified example of theconstitution of the latch module in the third embodiment.

FIG. 14 is a diagram illustrating a second modified example of theconstitution of the latch module in the third embodiment.

FIG. 15 is a diagram illustrating a third modified example of theconstitution of the latch module in the third embodiment.

FIG. 16 is a diagram illustrating a fourth modified example of theconstitution of the latch module in the third embodiment.

FIG. 17 is a diagram illustrating a fifth modified example of theconstitution of the latch module in the third embodiment.

FIG. 18 is a diagram illustrating an example of a housing with awaterproof structure in the third embodiment.

FIG. 19 is a diagram illustrating an example of a constitution of alatch system in a fourth embodiment.

FIG. 20 is a diagram illustrating a case in which a first antennareceives radio waves in an example of the constitution of the latchsystem in the fourth embodiment.

FIG. 21 is a diagram illustrating a case in which a second antennareceives radio waves in an example of the constitution of the latchsystem in the fourth embodiment.

FIG. 22 is a diagram illustrating an example of a constitution of apower detector in the fourth embodiment.

FIG. 23 is a diagram illustrating an example of a constitution of thepower detector having gain switching in the fourth embodiment.

FIG. 24 is a diagram illustrating an example of a constitution of acircuit of the power detector having gain switching in the fourthembodiment.

FIG. 25 is a diagram illustrating an example of a housing with awaterproof structure in the fourth embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[Constitution of Latch System 100]

A constitution of a latch system 100 will be described below withreference to the drawings.

FIG. 1 is a diagram illustrating an example of the constitution of thelatch system 100 in an embodiment. As illustrated in FIG. 1 , the latchsystem 100 includes a transmitter 70 and a latch module 1.

The transmitter 70 is a terminal in which radio waves can betransmitted. Here, for example, the radio waves are radio wavestransmitted by a transmission-side device during wireless communicationperformed in accordance with a communication standard such as Bluetooth(registered trademark) or Wi-Fi (registered trademark). The radio wavesare not limited to a communication standard such as Bluetooth(registered trademark) or Wi-Fi (registered trademark), variouscommunication methods can be adopted for the radio waves, and the radiowaves may be transmitted through communication according to a uniquestandard in which the default communication standard is not satisfied.

For example, the transmitter 70 is a mobile information processingterminal in which wireless communication is possible such asmultifunctional mobile phone terminals (smartphones), mobile phoneterminals, personal digital assistants (PDAs), notebook PCs, and tabletPCs. The transmitter 70 is not limited to a mobile informationprocessing terminal and may be another information processing terminal.

In this example, the transmitter 70 transmits radio waves 71.

The latch module 1 includes a power supply 50, a load 60, and a latchcircuit 10. The latch module 1 receives the radio waves 71 transmittedfrom the transmitter 70.

The power supply 50 is a power supply configured to output directcurrent (DC) electric power. For example, the power supply 50 is abattery such as a lithium battery. When the latch module 1 is asmall-sized device, the power supply 50 may be a battery as installed ina board. The power supply 50 supplies electric power to the load 60.

The load 60 has functions such as communication functions. For example,the load 60 may include a read only memory (ROM) (not shown), a randomaccess memory (RAM) (not shown), and a central processing unit (CPU)(not shown).

The latch circuit 10 is connected between the power supply 50 and theload 60. The power supply 50 supplies electric power to the load 60 viathe latch circuit 10.

The latch circuit 10 receives the radio waves 71 transmitted from thetransmitter 70. The latch circuit 10 receives the radio waves 71transmitted from the transmitter 70 to control a conduction statebetween the power supply 50 and the load 60. Hereinafter, the latchcircuit 10 is also referred to as an “electronic circuit.”

First Embodiment

A first embodiment of the present invention will be described below withreference to the drawings.

FIG. 2 is a diagram illustrating an example of a constitution of thelatch module 1 in the first embodiment. In FIG. 2 , the latch module 1includes a latch circuit 10, a power supply 50, and a load 60.

The latch circuit 10 includes an antenna 140, a power conversion circuit110, a control circuit 120, and a switch 130.

The antenna 140 is connected to the power conversion circuit 110. Theantenna 140 receives radio waves 71 transmitted from a transmitter 70.

The power conversion circuit 110 includes a power input terminal 111 asan input terminal and a DC power output terminal 112 as an outputterminal. Radio waves received by the antenna 140 are input to the powerinput terminal 111. The electric power obtained by the radio wavesreceived by the antenna 140 is converted into DC electric power andoutput. The DC power output terminal 112 outputs the DC electric powerconverted by the power conversion circuit 110. That is to say, the powerconversion circuit 110 includes the power input terminal 111 to whichthe electric power obtained by the radio waves received by the antenna140 capable of receiving radio waves is input and the DC power outputterminal 112 configured to output DC electric power. Furthermore, thepower conversion circuit 110 converts the electric power input to thepower input terminal 111 into DC electric power and the converted DCelectric power is output from the DC power output terminal 112.

The power conversion circuit 110 may include an RF-DC conversion circuit113 and a booster circuit 114.

The RF-DC conversion circuit 113 converts the electric power obtained bythe radio waves input to the power input terminal 111 into DC electricpower. The RF-DC conversion circuit 113 outputs the converted DCelectric power to the booster circuit 114.

The booster circuit 114 steps up a voltage of the DC electric powerconverted by the RF-DC conversion circuit 113. The booster circuit 114outputs the stepped-up electric power via the DC power output terminal112.

The control circuit 120 includes an input terminal 121 connected to theDC power output terminal 112 of the power conversion circuit 110 and anoutput terminal 122 connected to the switch 130 and configured tocontrol a connection state of the switch 130. The control circuit 120includes a power supply terminal 123 as a power source terminal.

The DC electric power output by the power conversion circuit 110 isinput to the input terminal 121. The output terminal 122 outputs anoutput signal corresponding to a state of the input terminal 121.Electric power is supplied from the power supply 50 to the power supplyterminal 123.

The switch 130 is connected between the power supply 50 configured tooutput DC electric power and the load 60 driven through the DC electricpower supplied from the power supply 50. The switch 130 switches aconnection state between the power supply 50 and the load 60 from anon-conduction state to a conduction state.

The non-conduction state is a state in which the supply of electricpower from the power supply 50 to the load 60 is cut off and theconduction state is a state in which electric power is supplied from thepower supply 50 to the load 60.

In this example, the control circuit 120 includes a flip-flop 127. Theflip-flop 127 switches a control signal output from the output terminal122.

Although FIG. 2 illustrates an example in which a D flip-flop (a D-F/F)is utilized for the flip-flop 127, the D-F/F may be composed of anotherflip-flop such as a T flip-flop.

The control circuit 120 controls the conduction state of the switch 130.Specifically, the control circuit 120 controls the connection state ofthe switch 130 to be in a conduction state when the power conversioncircuit 110 outputs DC electric power due to the antenna 140 receivingthe radio waves 71.

More specifically, the input terminal 121 of the control circuit 120 isconnected to a CLK terminal 1271 and a D terminal 1272 of the flip-flop127. Furthermore, the output terminal 122 of the control circuit 120 isconnected to a Q terminal 1273 of the flip-flop 127.

Since the input terminal 121 has a low level (the same potential as aground potential) in a state in which the antenna 140 is not receivingthe radio waves 71 (that is, in a state in which the transmitter 70 isdistant from the latch circuit 10 or the radio waves 71 are not beingtransmitted from the transmitter 70), the Q terminal 1273 has the lowlevel held therein. In this state, the switch 130 is controlled suchthat it is brought into a non-conduction state. That is to say, in thisstate, electric power is not supplied from the power supply 50 to theload 60.

The RF-DC conversion circuit 113 outputs DC electric power to thebooster circuit 114 in a state in which the antenna 140 is receiving theradio waves 71 (that is, in a state in which the radio waves 71 arebeing transmitted from the transmitter 70 or the transmitter 70 isbrought closer to the latch circuit 10). The booster circuit 114performs stepping-up until the Q terminal 1273 of the flip-flop 127 hasa changing threshold value potential or more. At this time, in the powerconversion circuit 110, a potential sufficient to change a state of theQ terminal 1273 is input to the CLK terminal 1271 and the D terminal1272 of the flip-flop 127. Thus, the level of the Q terminal 1273 ischanged to a high level. In this state, the switch 130 is controlled tobe in a conduction state.

If the switch 130 is controlled to be in a conduction state, the powersupply 50 supplies electric power to the load 60 via the switch 130.

Since electric power is supplied from the power supply 50 to theflip-flop 127, even if the antenna 140 transitions to a state in whichthe antenna 140 does not receive the radio waves 71 (that is, a state inwhich the latch circuit 10 does not receive radio waves due to reasonssuch as the transmitter 70 moving to a position in which the transmitteris distance from the latch circuit 10), the Q terminal 1273 continues tooutput a high level.

In this embodiment, when the switch 130 is switched to be in aconduction state, the control circuit 120 keeps the switch 130conductive using electric power supplied from the power supply 50 to thepower supply terminal 123.

In this example, since the flip-flop 127 is connected to the powersupply 50 via the power supply terminal 123, a constitution in which theflip-flop 127 with low power consumption is selected to significantlyminimize an influence on a battery lifespan may be provided. Forexample, a flip-flop with low power consumption of less than 1 μA(microampere) may be selected.

FIG. 3 is a diagram illustrating a first modified example of theconstitution of the latch module 1 in the first embodiment. A latchmodule 1 b illustrated in FIG. 3 is a first modified example of thelatch module 1. A constituent element in the first modified example thatis the same as the latch module 1 described above will be denoted by thesame reference numeral and a description thereof will be omitted. Thelatch module 1 b is different from the latch module 1 described above inthat the latch module 1 b includes a control circuit 120 b instead ofthe control circuit 120.

The control circuit 120 b includes an input terminal 121 b connected toa DC power output terminal 112 of a power conversion circuit 110 and anoutput terminal 122 b connected to a switch 130 and configured tocontrol a connection state of the switch 130. Furthermore, the controlcircuit 120 b includes a power supply terminal 123 b as a power supplyterminal.

DC electric power output by the power conversion circuit 110 is input tothe input terminal 121 b. The output terminal 122 b outputs an outputsignal corresponding to a state of the input terminal 121 b. Electricpower is supplied from a power supply 50 to the power supply terminal123 b.

In this example, the control circuit 120 b includes a power detector126. The power detector 126 includes a detection input terminal 1261, areference input terminal 1262, and a voltage detection output terminal1263 as input/output terminals. The reference input terminal 1262 isconnected to a ground point TG. The voltage detection output terminal1263 outputs a potential corresponding to a potential of the detectioninput terminal 1261 and a potential of the reference input terminal1262.

In a state in which an antenna 140 does not receive radio waves 71 (thatis, in a state in which a transmitter 70 is distance from a latchcircuit 10 or radio waves 71 is not transmitted from the transmitter70), the input terminal 121 b has a low level. Thus, the low level isinput to the detection input terminal 1261. Since the reference inputterminal 1262 is connected to the ground point TG (fixed to the lowlevel), the voltage detection output terminal 1263 outputs the lowlevel. In this state, the switch 130 is controlled to be in anon-conduction state.

In a state in which the antenna 140 is receiving radio waves 71 (thatis, in a state in which radio waves 71 are being transmitted from thetransmitter 70 or the transmitter 70 is brought closer to the latchcircuit 10), an RF-DC conversion circuit 113 outputs DC electric powerto a booster circuit 114. The booster circuit 114 steps up a potentialof a power detector 126 to an operation potential (a high level)thereof. The power conversion circuit 110 outputs a high level. Sincethe high level is input to the detection input terminal 1261 of thepower detector 126, the voltage detection output terminal 1263 outputs ahigh level. In this state, the switch 130 is controlled to be in aconduction state.

In this example, the detection input terminal 1261 of the power detector126 is connected to the voltage detection output terminal 1263.

The control circuit 120 b may include a resistor 124 b. In this case,the detection input terminal 1261 of the power detector 126 is connectedto the voltage detection output terminal 1263 via the resistor 124 b. Asan example, a resistance value of the resistor 124 b may be 10 mega-ohmsor more. When the control circuit 120 b includes the resistor 124 b, itis possible to further minimize power consumption.

When the power detector 126 outputs a high level to control the switch130 to be in a conduction state and thus the power supply 50 isconnected to a load 60, a current flowing through the control circuit120 b only flows through the resistor 124 b and electric currentconsumption of the power detector 126, both of which are small.

In this way, since the power consumption of the power detector 126 istheoretically zero, the power consumption of the power supply 50 inwhich the switch 130 is in a non-conduction state can be changed tosubstantially zero. Therefore, in the example in which the powerdetector 126 is provided, it is possible to further reduce powerconsumption as compared with the example described above in which theflip-flop 127 is provided.

FIG. 4 is a diagram illustrating an example of a constitution of thepower detector 126 in the first embodiment.

In FIG. 4 , (A) is an example of the constitution of the power detector126, and the power detector 126 includes a transistor Q1, a transistorQ2, a transistor Q3, a transistor Q4, an inverter 1264, and a resistor1265.

The transistor Q1, the transistor Q2, and the transistor Q4 areenhancement elements. The transistor Q3 is a depression element.

When the output terminal 122 b outputs a low level, the transistor Q2and the transistor Q3 are turned on. When the output terminal 122 boutputs a high level, the transistor Q1 and the transistor Q4 are turnedon.

In this example, a current flows from the power supply terminal 123 b tothe ground point TG through two routes. A first route is a route inwhich a current flows from the power supply terminal 123 b to the groundpoint TG via the transistor Q1 and the transistor Q3 and a second routeis a route in which a current flows from the power supply terminal 123 bto the ground point TG via the transistor Q2 and the transistor Q4. Thepower detector 126 cuts off both of the routes in which a current flowsfrom the power supply terminal 123 to the ground point TG all the time,regardless of the state of the output terminal 122 b.

Therefore, the power consumption of the power detector 126 istheoretically zero.

In FIG. 4 , (B) is a truth value table for an example of theconstitution of the power detector 126 illustrated in (A). (B)illustrates a correspondence relationship between potentials of theinput terminal 121 b and the output terminal 122 b and states of thetransistor Q1, the transistor Q2, the transistor Q3, and the transistorQ4.

IN indicates a level of the potential of the input terminal 121 b andOUT indicates a level of the potential of the output terminal 122 b. Thetransistor Q1, the transistor Q2, the transistor Q3, and the transistorQ4 indicate states of the transistors.

FIG. 5 is a diagram illustrating a second modified example of theconstitution of the latch module 1 in the first embodiment. A latchmodule 1 c illustrated in FIG. 5 is the second modified example of thelatch module 1. A constituent element in the second modified examplethat is the same as the latch module 1 described above will be denotedby the same reference numeral and a description thereof will be omitted.The latch module 1 c is different from that in a case in which a latchmodule 1 a and a latch module 1 b supply electric power to a powersupply terminal 123 c included in a control circuit 120 c. The controlcircuit 120 c is an example of the control circuit 120.

The control circuit 120 c includes an input terminal 121 c connected toa DC power output terminal 112 of a power conversion circuit 110 and anoutput terminal 122 c connected to a switch 130 and configured tocontrol a connection state of the switch 130. Furthermore, the controlcircuit 120 c includes the power supply terminal 123 c as a power supplyterminal.

DC electric power output by the power conversion circuit 110 is input tothe input terminal 121 c. The output terminal 122 c outputs an outputsignal corresponding to a state of the input terminal 121 c. Electricpower is supplied from at least one of the power conversion circuit 110and the power supply 50 to the power supply terminal 123 c.

In this example, the latch module 1 c includes a diode D1 and a diodeD2. The diode D1 has an anode connected to the DC power output terminal112 of the power conversion circuit 110 and a cathode connected to thepower supply terminal 123 c of the control circuit 120 c. The diode D2has an anode connected to a connection point between the switch 130 andthe load 60 and a cathode connected to the power supply terminal 123 cof the control circuit 120 c. Hereinafter, the diode D1 will be alsoreferred to as a “first diode” and the diode D2 will be also referred toas a “second diode.”

In a state in which the antenna 140 does not receive radio waves 71(that is, in a state in which the transmitter 70 is distance from thelatch circuit 10 or radio waves 71 are not transmitted from thetransmitter 70), electric power is not supplied to the control circuit120 c. In this case, the switch 130 is controlled to be in anon-conduction state. The output terminal 122 c may be fixed at a lowlevel using a resistor (not shown) or the like.

In a state in which the antenna 140 is receiving radio waves 71 (thatis, in a state in which radio waves 71 are being transmitted from thetransmitter 70 or the transmitter 70 is brought closer to the latchcircuit 10), an RF-DC conversion circuit 113 outputs DC electric powerto the booster circuit 114. The booster circuit 114 steps up the DCelectric power to a potential of a potential or more obtained by addingan amount corresponding to a stepped-down voltage of the diode D1 to anoperation potential of the power detector 126. The power conversioncircuit 110 supplies electric power from the DC power output terminal112 to the power supply terminal 123 c of the control circuit 120 c viathe diode D1.

In this case, a potential output from the DC power output terminal 112of the power conversion circuit 110 is also input to the input terminal121 c of the control circuit 120 c. If a high level is input to theinput terminal 121 c, the control circuit 120 c outputs a high level tothe output terminal 122 c. Therefore, the switch 130 is controlled to bein a conduction state.

If the switch 130 is controlled to be in the conduction state, the powersupply 50 supplies electric power to the power supply terminal 123 c ofthe control circuit 120 c via the switch 130 and the diode D2.

Even if the antenna 140 does not receive radio waves 71 (that is, astate in which the latch circuit 10 no longer receives radio waves dueto reasons such as the transmitter 70 moving distance from the latchcircuit 10) transitions, the control circuit 120 c can receive thesupply of electric power from the power supply 50 via the switch 130 andthe diode D2.

Therefore, in this embodiment, in the switch 130, if the switch 130 iscontrolled to be in a conduction state when the antenna 140 receives theradio waves 71, the switch 130 is kept conductive.

FIG. 6 is a diagram illustrating an example of a housing with awaterproof structure in the first embodiment. As illustrated in FIG. 6 ,a latch waterproof module 2 includes the latch circuit 10, the powersupply 50 configured to output DC electric power, the load 60 configuredto be driven by DC electric power supplied from the power supply 50, anda housing 80.

The housing 80 includes the latch circuit 10, the power supply 50, andthe load 60 accommodated therein. The housing 80 has waterproofperformance.

Summary of Effects of the First Embodiment

According to the embodiment described above, the latch circuit 10controls a connection state between the power supply 50 and the load 60to be in a conduction state using the radio waves received by theantenna 140.

In the related art, in the small-sized device as shipped with thebattery installed in the board, electric power is supplied the momentthe battery is installed, and the consumption of the battery begins.Although it is desirable that electric power be supplied only after thedevice is delivered to a customer or when a customer intends to supplyelectric power in view of a battery lifespan, contact switches,(removable) insulating films, and the like lead to an increase in sizeof the small-sized device.

The latch circuit 10 can minimize an increase in size of the small-sizeddevice by controlling a connection state between the power supply 50 andthe load 60 to be in a conduction state using the radio waves receivedby the antenna 140.

Also, according to the above-described embodiment, in the latch circuit10, the power conversion circuit 110 converts the electric powerobtained by the radio waves received by the antenna 140 into DC electricpower and the control circuit 120 controls a conduction state of theswitch 130. Since the latch circuit 10 can switch a state of the switch130 to be in a conduction state even using weak radio waves whenincluding the control circuit 120, it does not take time to start up theAFE which is a load. Thus, it is possible to provide the latch module 1in which it does not take time from the reception of radio waves to thestarting-up of the load 60.

Therefore, it is possible to provide the convenient latch circuit 10.

Also, according to the above-described embodiment, the control circuit120 included in the latch circuit 10 receives electric power suppliedfrom the power supply 50. Therefore, after the antenna 140 receivesradio waves, the latch circuit 10 can keep the connection state of theswitch 130 conductive even in a state in which the antenna 140 does notreceive radio waves.

Furthermore, according to the above-described embodiment, the controlcircuit 120 includes the flip-flop 127. Therefore, the control circuit120 can switch and keep the connection state of the switch 130 using asimple constitution.

Also, according to the above-described embodiment, the control circuit120 includes the power detector 126 having feedback.

Since the output signal of the control circuit 120 is fed back to theinput, the control circuit 120 can maintain the connection state of theswitch 130. Furthermore, it is possible to maintain the state of theswitch 130 with low power consumption.

Furthermore, according to the above-described embodiment, the powerdetector 126 further includes the resistor 124 b in which 10 mega-ohmsor more is provided. Therefore, when the control circuit 120 includesthe resistor 124 b, it is possible to further minimize electric powerconsumed by the control circuit 120.

In addition, according to the above-described embodiment, when the latchmodule 1 includes the diode D1, the power conversion circuit 110provides electric power of the control circuit 120. Therefore, the latchmodule 1 can obtain electric power for switching the switch 130 to aconduction state from radio waves received by the antenna 140. That isto say, the latch module 1 can switch the switch 130 to a conductionstate without consuming electric power of the power supply 50.

Moreover, according to the above-described embodiment, when the latchmodule 1 includes the diode D2, after the switch 130 is controlled to bein a conduction state, it is possible to receive the supply of electricpower from the power supply 50. Therefore, the switch 130 can maintainthe conduction state.

In addition, according to the above-described embodiment, the latchmodule 1 is accommodated in the housing 80 with waterproof performance.For example, when the starting-up of the system is required in anon-contact state in a device used in a sealed state in water, it ispossible to start up the system in a non-contact state by applying thelatch module 1 in this embodiment.

Examples of the device used in a sealed state in water a water qualitymeasurement device, a small-sized camera device, and the like.Furthermore, the expression “in water” includes not only water but alsoa wide range of liquids such as electrolytic solutions and body fluids.

Second Embodiment

A second embodiment of the present invention will be described belowwith reference to the drawings.

FIG. 7 is a diagram illustrating an example of a power conversioncircuit 110 d in the second embodiment. The power conversion circuit 110d is an example of the power conversion circuit 110.

In FIG. 7 , the power conversion circuit 110 d includes a firstcapacitor C11, a first diode D11, a second diode D12, and a secondcapacitor C12.

The first capacitor C11 includes a first electrode C11 a and a secondterminal C11 b. The first electrode C11 a of the first capacitor C11 isconnected to a power input terminal 111 a and a second electrode C11 bis connected to a connection point between a cathode of the first diodeD11 and an anode of the second diode D12.

The first diode D11 has an anode connected to a ground point TG and thecathode connected to the second electrode C11 b of the first capacitorC11.

The second capacitor C12 includes a first electrode C12 a and a secondelectrode C12 b. The first electrode C12 a of the second capacitor C12is connected to the DC power output terminal 112 d and the secondelectrode C12 b is connected to the ground point TG.

The second diode D12 has an anode connected to a power input terminal111 d via a capacitor. In the case of this example, the anode of thesecond diode D12 is connected to the power input terminal 111 d via thefirst capacitor C11. Furthermore, the second diode D12 has a cathodeconnected to the first electrode C12 a of the second capacitor C12.

If a positive potential is applied to the power input terminal 111 d, acurrent I11 flows from the power input terminal 111 d via the firstcapacitor C11 and the second diode D12. Electric charges are accumulatedin the second capacitor C12 through the current I11.

If a negative potential is applied to the power input terminal 111 d, acurrent I12 flows from the ground point TG via the first diode D11 andthe first capacitor C11. Electric charges are accumulated in the firstcapacitor C11 through the current I12.

When a positive potential is applied to the power input terminal 111 dagain, a current I11 flows from the power input terminal 111 d via thefirst capacitor C11 and the second diode D12. As a result, a potentialtwice that of the power input terminal 111 d is output to the DC poweroutput terminal 112 d. This is an operation of a half-wave voltagedoubler rectifier circuit.

The power conversion circuit 110 d is a voltage doubler rectifiercircuit configured to step up weak radio waves. The weak radio wavesuses, for example, a 2.4 GHz band such as a Bluetooth (registeredtrademark) low Energy (LE) (hereinafter referred to as a “BLE”) standardcommunication method installed in a smartphone or the like. It isdesirable that the first diode D11 and the second diode D12(hereinafter, when diodes provided in the power conversion circuit 110are not distinguished, they are referred to as a “diode D”) haveexcellent high frequency characteristics, a low forward voltage, and asmall capacitance between terminals. In this example, the diode D may bea Schottky barrier diode.

In the first capacitor C11 and the second capacitor C12 (hereinafter,when capacitors provided in the power conversion circuit 110 are notdistinguished, they are referred to as a “capacitor C”), a response rateand an arrival voltage value of a stepped-up voltage change inaccordance with a capacitance. Furthermore, if the capacitor C does nothave a sufficient capacitance value, an amount of ripple (an amount ofvoltage fluctuation) of an output voltage increases and DCcharacteristics deteriorate. On the other hand, if the capacitor C has atoo large capacitance value, it takes time to charge and responsivenessdeteriorates.

Therefore, the capacitance value of the capacitor C is adjusted to avalue at which well-balanced and good voltage doubler characteristicscan be obtained for each application of the selected diode D and latchcircuit 10. For example, in this embodiment, 33 pF, 24 pF, and the likeare preferable at 2.4 GHz.

An optimum capacitance value changes depending on a stray capacitance, aboard pattern, an installation layout, and the like of a board. In thecircuit illustrated in FIG. 7 , an optimum value changes in the range ofseveral to several tens of pF. An optimum capacitance value needs to beconfirmed in accordance with a stray capacitance, a board pattern, aninstallation layout, and the like of a board.

When the power conversion circuit 110 has a constitution in which theabove-described voltage doubler rectifier circuit is incorporated inmultiple stages, it is possible to obtain a potential at which thecontrol circuit 120 can operate even with weaker radio waves.

FIG. 8 is a diagram illustrating the power conversion circuit 110 ewhich is a first modified example of the power conversion circuit 110 inthe second embodiment. The power conversion circuit 110 e is an exampleof the power conversion circuit 110 described above. A constituentelement in the first modified example that is the same as the powerconversion circuit 110 described above will be denoted by the samereference numeral and a description thereof will be omitted.

In FIG. 8 , a power conversion circuit 110 e includes a first capacitorC21, a first diode D21, a second capacitor C22, a second diode D22, athird capacitor C23, a third diode D23, a fourth capacitor C24, and afourth diode D24.

In this example, the first capacitor C21, the first diode D21, thesecond capacitor C22, and the second diode D22 are the same as the firstcapacitor C11, the first diode D11, the second capacitor C12, and thesecond diode D12, respectively.

When the power conversion circuit 110 e further includes the thirdcapacitor C23, the third diode D23, the fourth capacitor C24, and thefourth diode D24 as compared with the power conversion circuit 110 d, atwo-stage voltage doubler rectifier circuit is constituted.

The third capacitor C23 includes a first electrode C23 a and a secondelectrode C23 b. The first electrode C23 a of the third capacitor C23 isconnected to a cathode of the third diode D23 and the second electrodeC23 b is connected to a ground point TG.

The third diode D23 has an anode connected to a second electrode C21 bof the first capacitor C21 and the cathode connected to the firstelectrode C23 a of the third capacitor C23.

The fourth capacitor C24 includes a first electrode C24 a and a secondelectrode C24 b. The first electrode C24 a of the fourth capacitor C24is connected to a power input terminal 111 e and the second electrodeC24 b is connected to a cathode of the fourth diode D24.

The fourth diode D24 has an anode connected to a connection pointbetween the cathode of the third diode D23 and the first electrode C23 aof the third capacitor C23 and the cathode connected to the secondelectrode C24 b of the fourth capacitor C24.

Also, in the case of this example, the anode of the second diode D22 isconnected to the power input terminal 111 e via the fourth capacitorC24.

In the example illustrated in FIG. 8 , a voltage four times an inputvoltage input to the power input terminal 111 e can be output from theDC power output terminal 112 e.

When the multi-stage voltage doubler rectifier circuit is constituted inthis way, the power conversion circuit 110 can obtain a potential atwhich the control circuit 120 can operate.

Here, when the multi-stage voltage doubler rectifier circuit isconstituted, it causes a decrease in RF-DC conversion efficiency.Furthermore, the manufacturing cost increases due to an increase in thenumber of parts constituting the multi-stage voltage doubler rectifiercircuit. Therefore, it is desirable to set the number of stagesappropriate for each application.

FIG. 9 is a diagram illustrating a power conversion circuit 110 f whichis a second modified example of the power conversion circuit 110 in thesecond embodiment. The power conversion circuit 110 f is an example ofthe power conversion circuit 110 described above. A constituent elementin the second modified example that is the same as the power conversioncircuit 110 described above will be described by the same referencenumeral and a description thereof will be omitted.

In FIG. 9 , the power conversion circuit 110 f includes a first thecapacitor C31, a first diode D31, a second capacitor C32, a second diodeD32, a third capacitor C33, a third diode D33, a fourth capacitor C34, afourth diode D34, a fifth capacitor C35, a fifth diode D35, a sixthcapacitor C36, and a sixth capacitor C36.

In this example, the first the capacitor C31, the first diode D31, thesecond capacitor C32, the second diode D32, the third capacitor C33, thethird diode D33, the fourth capacitor C34, and the fourth diode D34 arethe same as the first capacitor C21, the first diode D21, the secondcapacitor C22, the second diode D22, the third capacitor C23, the firstdiode D23, the fourth capacitor C24, and the fourth diode D24,respectively.

The power conversion circuit 110 f further includes a fifth capacitorC35, a fifth diode D35, a sixth capacitor C36, and a sixth diode D36compared with the power conversion circuit 110 e to constitute athree-stage voltage doubler rectifier circuit.

The fifth capacitor C35 includes a first electrode C35 a and a secondelectrode C35 b. The first electrode C35 a of the fifth capacitor C35 isconnected to a cathode of the fifth diode D35 and the second electrodeC35 b is connected to the ground point TG.

The fifth diode D35 has an anode connected to a second electrode C34 bof the fourth capacitor C34 and the cathode connected to the firstelectrode C35 a of the fifth capacitor C35.

The sixth capacitor C36 includes a first electrode C36 a and a secondelectrode C36 b. The first electrode C36 a of the sixth capacitor C36 isconnected to a power input terminal 111 f and the second electrode C36 bis connected to a cathode of the sixth diode D36.

The sixth diode D36 has an anode connected to a connection point betweenthe cathode of the fifth diode D35 and the first electrode C35 a of thefifth capacitor C35 and the cathode connected to the second electrodeC36 b of the sixth capacitor C36.

Also, in the case of this example, the anode of the second diode D32 isconnected to the power input terminal 111 f via the sixth capacitor C36.

In the example illustrated in FIG. 9 , a voltage which is six times aninput voltage input to the power input terminal 111 f can be output fromthe DC power output terminal 112 f.

When the multi-stage voltage doubler rectifier circuit is constituted inthis way, the power conversion circuit 110 can obtain a potential atwhich the control circuit 120 can operate. In the example associatedwith the power conversion circuit 110 f, the control circuit 120 can beoperated by weaker radio waves as compared with the example associatedwith the power conversion circuit 110 e.

Summary of Effects of Second Embodiment

According to the embodiment described above, the latch circuit 10illustrated in FIG. 1 constitutes the power conversion circuit 110 usingthe voltage doubler rectifier circuit. When the latch circuit 10constitutes the power conversion circuit 110 using the voltage doublerrectifier circuit, it is possible to generate DC electric powerstepped-up from that of weak radio waves. The power conversion circuit110 can drive the control circuit 120 by supplying the stepped-up DCelectric power to the control circuit 120.

Also, according to the above-described embodiment, the voltage doublerrectifier circuit is constituted of the capacitor C and the diode D.Therefore, the latch circuit 10 can constitutes the power conversioncircuit 110 with a simple constitution.

Furthermore, according to the above-described embodiment, the latchcircuit 10 constitutes the power conversion circuit 110 using thetwo-stage voltage doubler rectifier circuit. When the latch circuit 10constitutes the power conversion circuit 110 using the two-stage voltagedoubler rectifier circuit, it is possible to drive the control circuit120 even with weak radio waves. When the latch circuit 10 drives thecontrol circuit 120 even with weak radio waves, it is possible tocontrol the power supply 50 and the load 60 to be in a conduction state.

In addition, according to the above-described embodiment, the latchcircuit 10 constitutes the power conversion circuit 110 using thethree-stage voltage doubler rectifier circuit. When the latch circuit 10constitutes the power conversion circuit 110 using the three-stagevoltage doubler rectifier circuit, it is possible to drive the controlcircuit 120 even with weaker radio waves compared with the two-stagevoltage doubler rectifier circuit. The latch circuit 10 can control thepower supply 50 and the load 60 to be in a conduction state by drivingthe control circuit 120 even with weaker radio waves.

Third Embodiment

A third embodiment of the present invention will be described below withreference to the drawings.

FIG. 10 is a diagram illustrating an example of a first antenna 240 anda second antenna 340 in a third embodiment. In FIG. 10 , (A) is adiagram illustrating an example of a constitution of a case in which thelatch module 1 described above includes one antenna 140. In this case,the radio waves received by the antenna 140 is converted into DCelectric power by the power conversion circuit 110 and input to thecontrol circuit 120.

The control circuit 120 controls the switch 130 from a non-conductionstate to a conduction state. In the case of this example, the controlcircuit 120 cannot control the switch 130 from a conduction state to anon-conduction state.

In FIG. 10 , (B) is a diagram illustrating an example of a constitutionin a case in which the latch module 1 includes two antennas (a firstantenna 240 and a second antenna 340). In this case, the latch module 1includes the first antenna 240, a first power conversion circuit 210,the second antenna 340, a second power conversion circuit 310, and acontrol circuit 220.

In this example, the first antenna 240 and the second antenna 340 may beprovided at different angles from each other.

The first antenna 240 is provided to be able to receive first radiowaves in a first direction.

The first power conversion circuit 210 includes a first power inputterminal 211 and a first DC power output terminal 212. The first powerinput terminal 211 is connected to the first antenna 240. The first DCpower output terminal 212 is connected to the control circuit 220.

The electric power obtained by the first radio waves received by thefirst antenna 240 is input to the first power input terminal 211. If theelectric power is input to the first power input terminal 211, the firstpower conversion circuit 210 converts the electric power input to thefirst power input terminal 211 into DC electric power. The first powerconversion circuit 210 outputs DC electric power from the first DC poweroutput terminal 212.

The second antenna 340 is provided to be able to receive second radiowaves in a second direction different from the first direction.

The second power conversion circuit 310 includes a second power inputterminal 311 and a second DC power output terminal 312. The second powerinput terminal 311 is connected to the second antenna 340. The second DCpower output terminal 312 is connected to the control circuit 220.

The electric power obtained by the second radio waves received by thesecond antenna 340 is input to the second power input terminal 311. Ifthe electric power is input to the second power input terminal 311, thesecond power conversion circuit 310 converts the electric power input tothe second power input terminal 311 into DC electric power. The secondpower conversion circuit 310 outputs DC electric power from the secondDC power output terminal 312.

The control circuit 220 includes, as input/output terminals, a firstinput terminal 221, a second input terminal 225, and an output terminal222.

The first input terminal 221 is connected to the first DC power outputterminal 212 of the first power conversion circuit 210. The second inputterminal 225 is connected to the second DC power output terminal 312 ofthe second power conversion circuit 310. The output terminal 222 isconnected to the switch 130 and controls the connection state of theswitch 130.

The control circuit 220 controls the connection state of the switch 130to be in a conduction state when the first power conversion circuit 210outputs DC electric power due to the reception of the first radio wavesby the first antenna 240. The control circuit 220 controls theconnection state of the switch 130 to be in a non-conduction state whenthe second power conversion circuit 310 outputs DC electric power due tothe reception of the second radio waves by the second antenna 340.

In this way, in the example illustrated in (B) of FIG. 10 , the controlcircuit 220 can not only control the switch 130 from a non-conductionstate to a conduction state, but also control the switch 130 from aconduction state to a non-conduction state.

FIG. 11 is a diagram illustrating an example of the first antenna 240and the second antenna 340 in the third embodiment.

In FIG. 11 , (A) is a diagram illustrating an example of an electricfield antenna 500 in the third embodiment. (A) illustrates an example ofa type of antenna when the first antenna 240 or the second antenna 340is the electric field antenna 500.

When the first antenna 240 or the second antenna 340 is the electricfield antenna 500, the first antenna 240 or the second antenna 340 maybe a dipole antenna 501, a monopole antenna 502, an inverted F antenna503, a meander line antenna 504, or a chip antenna 505.

In FIG. 11 , (B) is a diagram illustrating an example of a magneticfield antenna 600 in the third embodiment. In FIG. 11 , (B) illustratesan example of a type of antenna when the first antenna 240 or the secondantenna 340 is the magnetic field antenna 600.

When the first antenna 240 or the second antenna 340 is the magneticfield antenna 600, the first antenna 240 or the second antenna 340 maybe a loop antenna 601.

The types of antennas of the first antenna 240 and the second antenna340 in this embodiment are not limited to the types of antennasillustrated in (A) and (B) of FIG. 11 . In addition, various antennascan be selected as the first antenna 240 and the second antenna 340.

FIG. 12 is a diagram illustrating an example of a constitution of alatch module 1 g in the third embodiment. The latch module 1 gillustrated in FIG. 6 is a modified example of the latch module 1 in thefirst embodiment. A constituent element in this example that is the sameas the latch module 1 described above will be denoted by the samereference numeral and a description thereof will be omitted.

In FIG. 6 , the latch module 1 g includes a latch circuit 10 g, a powersupply 50, and a load 60.

The latch circuit 10 g includes an electric field antenna 500 a, amagnetic field antenna 600 a, a first power conversion circuit 210 a, asecond power conversion circuit 310 a, a control circuit 220, and aswitch 130. The electric field antenna 500 a is an example of a firstantenna 240 and the magnetic field antenna 600 a is an example of asecond antenna 340.

The first power conversion circuit 210 a may include an RF-DC conversioncircuit 213 a and a booster circuit 214 a and the second powerconversion circuit 310 a may include an RF-DC conversion circuit 313 aand a booster circuit 314 a.

The electric field antenna 500 a receives first radio waves in a firstdirection. The electric power when the electric field antenna 500 areceives the first radio waves is input to the first power inputterminal 211 a of the first power conversion circuit 210 a. The firstpower conversion circuit 210 a converts the input electric power into DCelectric power and outputs the converted DC electric power to the firstDC power output terminal 212 a.

In this case, since the magnetic field antenna 600 a is installed to beable to receive second radio waves in a second direction different fromthe first direction, the magnetic field antenna 600 a does not receivethe first radio waves. Therefore, DC electric power is input to only thefirst input terminal 221 of the control circuit 220.

The magnetic field antenna 600 a receives the second radio waves in thesecond direction. Electric power when the magnetic field antenna 600 areceives the second radio waves is input to the second power inputterminal 311 a of the second power conversion circuit 310 a. The secondpower conversion circuit 310 a converts the input electric power into DCelectric power and outputs the converted DC electric power to the secondDC power output terminal 312 a.

In this case, since the electric field antenna 500 a is installed to beable to receive the first radio waves in the first direction differentfrom the second direction, the electric field antenna 500 a does notreceive the second radio waves. Therefore, DC electric power is input toonly the second input terminal 225 of the control circuit 220.

In this example, the control circuit 220 includes a flip-flop 227. Theflip-flop 227 switches a control signal outputs from the output terminal222 on the basis of a potential of the first input terminal 221 and apotential of the second input terminal 225.

Specifically, the flip-flop 227 is an SR flip-flop (SR-F/F). Morespecifically, the first input terminal 221 is connected to an S terminalof the flip-flop 227, the second input terminal 225 is connected to an Rterminal of the flip-flop 227, and the output terminal 222 is connectedto a Q terminal.

In a state in which the electric field antenna 500 a receives the firstradio waves, the first power conversion circuit 210 a outputs DCelectric power. The output DC electric power is input to the S terminalin which a potential according to the DC electric power corresponds tothat of the first input terminal 221 of the flip-flop 227. When theinput potential exceeds a threshold value voltage in which a state ofthe flip-flop 227 is caused to be changed, that is, if a high level isinput to the S terminal of the flip-flop 227, the Q terminal of theflip-flop 227 outputs a high level. In this state, the switch 130 iscontrolled to be in a conduction state. If the switch 130 is controlledto be in the conduction state, the power supply 50 supplies electricpower to the load 60.

In a state in which the magnetic field antenna 600 a receives the secondradio waves, the second power conversion circuit 310 a outputs DCelectric power. The output DC electric power is input to the R terminalin which a potential according to the DC electric power corresponds tothat of the second input terminal 225 of the flip-flop 227. When theinput potential exceeds a threshold value voltage in which a state ofthe flip-flop 227 is caused to be changed, that is, if a high level isinput to the R terminal of the flip-flop 227, the Q terminal of theflip-flop 227 outputs a low level. In this state, the switch 130 iscontrolled to be in a non-conduction state.

Electric power is supplied from the power supply 50 to the controlcircuit 220 including the flip-flop 227. Therefore, in a state in whichboth of the electric field antenna 500 a and the magnetic field antenna600 a do not receive radio waves, the flip-flop 227 continues to keep anoutput state of the Q terminal. That is to say, a connection state ofthe switch 130 differs depending on whether it is controlled to be in aconduction state or in a non-conduction state in accordance with whetherthe electric field antenna 500 a or the magnetic field antenna 600 afinally receives radio waves. If the switch 130 is controlled to be inthe non-conduction state, the power supply 50 stops the supply ofelectric power to the load 60.

In this example, since the flip-flop 227 is connected to the powersupply 50 via a power supply terminal 223, a constitution in which theflip-flop 227 with low power consumption is selected to significantlyminimize an influence on a battery lifespan may be provided. Forexample, a flip-flop with low power consumption of less than 1 μA(microampere) may be selected.

Also, the control circuit 220 may be composed of a low power consumptionlatch circuit having a function equivalent to that of a flip-flop.

FIG. 13 is a diagram illustrating a first modified example of theconstitution of the latch module 1 in the third embodiment. A latchmodule 1 h illustrated in FIG. 7 is a modified example of the latchmodule 1 g described above. A constituent element in this example thatis the same as the latch module 1 g will be denoted by the samereference symbol and a description thereof will be omitted. The latchmodule 1 h has a constitution different from that of the latch module 1g in that a power detector 226 is included in a control circuit 220 anda flip-flop 227 is not included.

A constitution of the control circuit 220 included in the latch module 1h is the same as that of the control circuit 120 b illustrated in FIG. 3. That is to say, a constitution of the power detector 226 included inthe control circuit 220 is the same as that of the power detector 126illustrated in FIG. 4 .

In the example associated with the latch module 1 h, a first DC poweroutput terminal 212 a of a first power conversion circuit 210 a isconnected to a first input terminal 221 of the control circuit 220. Thatis to say, when an electric field antenna 500 a receives first radiowaves, a current proportional to electric power due to the receivedradio waves is input to a detection input terminal 2261 of the powerdetector 226. In this case, when a potential proportional to the currentinput to an input terminal 2261 is higher than a reference inputpotential VDET in the power detector 226, a high level is output to avoltage detection output terminal 2263 and a switch 130 is controlled tobe in a conduction state.

Also, a second DC power output terminal 312 a of a second powerconversion circuit 310 a is connected to a second input terminal 225 ofthe control circuit 220. That is to say, when a magnetic field antenna600 a receives second radio waves, a current proportional to theelectric power obtained by the received radio waves is input to areference input terminal 2262 of the power detector 226. In the powerdetector 226, a current amplifier is present in the next stage of aninput terminal 2262. A current input to the reference input terminal2262 is amplified to be doubled using the current amplifier.Furthermore, a current adder in the next stage subtracts a current inputto the reference input terminal 2262 from a current input to thedetection input terminal 2261. When a potential proportional to thecurrent which has passed through the current adder is lower than thereference input potential VDET in the power detector 226, a low level isoutput to the voltage detection output terminal 2263 and the switch 130is controlled to be in a non-conduction state.

In this way, the latch module 1 h including the control circuit 220having the power detector 226 operates in the same manner as in thelatch module 1 g including the control circuit 220 a having theflip-flop 227.

When the latch module 1 h includes the power detector 226 in the controlcircuit 220, it is possible to further reduce power consumption ascompared with the latch module 1 g.

FIG. 14 is a diagram illustrating a second modified example of theconstitution of the latch module 1 in a third embodiment. A latch module1 i illustrated in FIG. 14 is a modified example of the latch module 1 gdescribed above. A constituent element in the second modified examplethat is the same as the latch module 1 g will be denoted by the samereference symbol and a description thereof will be omitted. The latchmodule 1 i has a different constitution from the latch module 1 g inthat an electric field antenna 500 is used for both a first antenna 240and a second antenna 340.

In the example illustrated in FIG. 14 , the electric field antenna 500 b(the first antenna 240) and the electric field antenna 500 c (the secondantenna 340) are provided at different positions from each other. Thatis to say, in the latch module 1 i, installation positions of theantennas are different from each other. Each of the installationpositions is a position in the latch module 1 i in which the antenna isinstalled.

The electric field antenna 500 b is installed to be able to receivefirst radio waves in a first direction. The electric field antenna 500 cis installed to be able to receive second radio waves in a seconddirection different from the first direction.

FIG. 15 is a diagram illustrating a second modified example of theconstitution of the latch module 1 in the third embodiment. A latchmodule 1 j illustrated in FIG. 15 is a third modified example of thelatch module 1 i described above. A constituent element in this examplethat is the same as the latch module 1 i will be denoted by the samereference symbol and a description thereof will be omitted. The latchmodule 1 j has a constitution different from that of the latch module 1i in that installation angles of the first antenna 240 and the secondantenna 340 are different from each other.

In this example illustrated in FIG. 15 , the latch module 1 j includesan electric field antenna 500 d and an electric field antenna 500 e. Theelectric field antenna 500 d is an example of the first antenna 240 andthe electric field antenna 500 e is an example of the second antenna340.

In the example illustrated in FIG. 15 , the electric field antenna 500 b(the first antenna 240) and the electric field antenna 500 c (the secondantenna 340) are provided at different angles. That is to say, since thefirst radio waves and the second radio waves are provided at differentangles, the first radio waves and the second radio waves do notinterfere with each other.

As an example, the electric field antenna 500 b (the first antenna 240)and the electric field antenna 500 c (the second antenna 340) may beprovided perpendicular to each other.

FIG. 16 is a diagram illustrating a fourth modified example of theconstitution of the latch module 1 in the third embodiment.

In FIG. 16 , (B) is a diagram illustrating the arrangement of an antenna701 and an antenna 702 using a two-dimensional Cartesian coordinatesystem of an x axis and a y axis. The antenna 701 illustrated in FIG. 9is an example of the first antenna 240 described above and the antenna702 is an example of the second antenna 340 described above.Hereinafter, when the antenna 701 and the antenna 702 are equivalent,the antenna 701 and the antenna 702 are referred to as an “antenna 700.”The antenna 700 is an example of the electric field antenna 500.

The antenna 701 is arranged along the x axis, and the antenna 702 isarranged along the y axis. In this example, the antenna 701 and theantenna 702 are arranged at different angles from each other.

In FIG. 16 , (B) is a diagram illustrating the arrangement of theantenna 701 and the antenna 702 using a three-dimensional Cartesiancoordinate system of an x axis, a y axis, and a z axis. In (B) of FIG.16 , the arrangement of the antenna 701 and the antenna 702 illustratedusing the two-dimensional Cartesian coordinate system of the x axis andthe y axis in (A) of FIG. 16 is illustrated in a three-dimensionalspace.

The antenna 701 and the antenna 702 are accommodated in a housing 703.Furthermore, the antenna 701 and the antenna 702 are arranged in thesame plane. When the antenna 701 and the antenna 702 are arranged atdifferent angles from each other as illustrated in (B) of FIG. 16 , evenwhen the antenna 701 and the antenna 702 are arranged on the same plane,the first radio waves and the second radio waves do not interfere witheach other.

FIG. 17 is a diagram illustrating a fifth modified example of theconstitution of the latch module 1 in the third embodiment. A latchmodule 1 k illustrated in FIG. 10 is a modified example of the latchmodule 1 j described above. A constituent element in this example thatis the same as the latch module 1 j will be denoted by the samereference symbols and a description thereof will be omitted. The latchmodule 1 k has a constitution different from that of the latch module 1j in that, although the installation angles of the first antenna 240 andthe second antenna 340 are the same, the first antenna 240 and thesecond antenna 340 include the dipole antennas 501 having differentlengths from each other.

In the example illustrated in FIG. 17 , the latch module 1 k includes anelectric field antenna 500 f and an electric field antenna 500 g. Theelectric field antenna 500 f is an example of the first antenna 240 andthe electric field antenna 500 g is an example of the second antenna340.

In this example, the electric field antenna 500 f and the electric fieldantenna 500 g includes antennas having lengths different from eachother. In order to minimize the interference between the first radiowaves and the second radio waves, the length of the electric fieldantenna 500 f and the length of the electric field antenna 500 g areselected on the basis of frequency of the radio waves. For example, thelength of the electric field antenna 500 f and the length of theelectric field antenna 500 g are preferably ½ or ¼ of wavelengths λ ofthe radio waves received by the antennas. In this case, the electricfield antenna 500 f and the electric field antenna 500 g can efficientlyreceive radio waves without generating reflected waves.

Specifically, when the frequency of the first radio waves is 2.4 GHz andthe frequency of the second radio waves is 5 GHz, a wavelength of thefirst radio waves is about 12.5 cm and a wavelength of the second radiowaves is about 6 cm. Furthermore, when a dipole antenna with awavelength of λ/2 is utilized, in each antenna, a length of the antennaconfigured to receive the first radio waves is 6.25 cm and a length ofthe antenna configured to receive the second radio waves is 3 cm.

As described above, when a constitution in which a latch module 1 k inwhich the dipole antenna 501 having an antenna length of ½ of thewavelengths λ of the first radio waves and the second radio waves ofdifferent wavelengths is utilized is provided, it is possible tominimize interference between the first radio waves and the second radiowaves. In this case, one of the radio waves can be used for turning onthe switch 130 and the other of the radio waves can be used for turnedoff the switch 130.

Although a case in which a length of the first antenna 240 and a lengthof the second antenna 340 are different has been described using anexample of the dipole antenna 501, the same applies not only to anexample of the dipole antenna 501, but also to the monopole antenna 502,the inverted F antenna 503, the meander line antenna 504, and the chipantenna 505. Similarly, these antennas may be configured so that alength of the antenna included in the first antenna 240 and a length ofthe antenna included in the second antenna 340 are different.

FIG. 18 is a diagram illustrating an example of a housing having awaterproof structure in the third embodiment. As illustrated in FIG. 11, a latch waterproof module 2 b includes a latch circuit 101, a powersupply 50 configured to output DC electric power, a load 60 driven by DCelectric power supplied from the power supply 50, and a housing 80.

The housing 80 includes the latch circuit 101, the power supply 50, andthe load 60 accommodated therein. The housing 80 has waterproofperformance.

Summary of Effects of Third Embodiment

According to the embodiment described above, the latch module 1 switchesa connection state of the switch 130 by detecting the first radio wavesreceived by the first antenna 240 and the second radio waves received bythe second antenna 340. The latch module 1 can switch the switch 130from a non-conduction state to a conduction state when configured inthis way. Furthermore, the latch module 1 can switch the switch 130 froma conduction state to a non-conduction state.

Also, according to the above-described embodiment, the first antenna 240and the second antenna 340 are provided at different positions from eachother. Therefore, the latch module 1 can prevent the first radio wavesin the first direction and the second radio waves in the directiondifferent from the first direction from interfering with each other.That is to say, it is possible to prevent malfunction.

Furthermore, according to the above-described embodiment, the firstantenna 240 and the second antenna 340 are provided at different anglesfrom each other. Therefore, the latch module 1 can prevent the firstradio waves in the first direction and the second radio waves in thedirection different from the first direction from interfering with eachother. That is to say, it is possible to prevent malfunction.

In addition, according to the above-described embodiment, the firstantenna 240 and the second antenna 340 are provided perpendicular toeach other. Therefore, according to the above-described embodiment, itis possible to prevent the first radio waves and the second radio wavesfrom interfering with each other. That is to say, it is possible toprevent malfunction.

Moreover, according to the above-described embodiment, the first antenna240 is the electric field antenna 500 and the second antenna 340 is themagnetic field antenna 600. Therefore, it is possible to prevent thefirst radio waves and the second radio waves from interfering with eachother. That is to say, it is possible to prevent malfunction.

Fourth Embodiment

A fourth embodiment of the present invention will be described belowwith reference to the drawings.

FIG. 19 is a diagram illustrating an example of a constitution of alatch system 100 in the fourth embodiment. In FIG. 19 , a latch module 1m includes a first antenna 740 a, a second antenna 740 b, a first powerconversion circuit 710 a, a second power conversion circuit 710 b, acontrol circuit 720, a switch 130, a power supply 50, and a load 60. Thefirst power conversion circuit 710 a may include an RF-DC conversioncircuit 713 a and a booster circuit 714 a and the second powerconversion circuit 710 b may include an RF-DC conversion circuit 713 band a booster circuit 714 b.

The first antenna 740 a is provided to be able to receive radio waves.The second antenna 740 b is provided to be able to receive radio wavesand has the same characteristics and gain as in the first antenna 740 a.The first antenna 740 a and the second antenna 740 b are arrangeddistance from each other at a prescribed distance.

In this example, a transmission point T1 indicates a point far distancefrom a point in which the first antenna 740 a is provided and a point inwhich the second antenna 740 b is provided. Specifically, the antennasare installed at locations in which the radio waves transmitted from thetransmission point T1 are in a far field.

Radio waves are divided into a far field and a near field in accordancewith a distance from the transmission point. For example, a boundaryposition between a far field and a near field is represented by λ/2πusing a wavelength λ of radio waves. As an example, at 2.4 GHz, about 2cm from a transmission point is a boundary between a far field and anear field.

Since radio waves can be regarded as plane waves in a far field, ifdistances from a transmission point are the same, an electric fieldintensity and a magnetic field intensity are the same. An intensity isinversely proportional to the first power of distance.

On the other hand, in a near field, in an electric field antenna, anelectric field intensity is inversely proportional to the third power ofdistance and a magnetic field intensity is inversely proportional to thesecond power of distance. In addition, in a magnetic field antenna, anelectric field intensity is inversely proportional to the second powerof distance and a magnetic field intensity is inversely proportional tothe third power of distance. That is to say, an electric field intensityand a magnetic field intensity in a near field have a significantlylarger change in intensity depending on a distance than in a far field.

When radio waves from a far field is received, the radio waves seen fromthe first antenna 740 a and the second antenna 740 b are plane waves andmagnitudes of electric powers P1 and P2 received by the antennas aresubstantially the same.

In this embodiment, the first antenna 740 a and the second antenna 740 bhave the same characteristics and gain. Thus, when each of the firstantenna 740 a and the second antenna 740 b receives radio waves from thetransmission point T1, the DC electric power output by the first powerconversion circuit 710 a and the DC electric power output by the secondpower conversion circuit 710 b are substantially the same.

In this example, radio waves from a far field are regarded as noise. Theradio waves from the far field are radio waves floating in theenvironment. For example, when the latch module 1 m receives the radiowaves from the far field, a malfunction in which a connection state ofthe switch 130 is switched is likely to be caused.

The first power conversion circuit 710 a includes a first power inputterminal 711 a to which electric power obtained when the first antenna740 a receives radio waves input and a first DC power output terminal712 a configured to output DC electric power, converts electric powerinput to the first power input terminal 711 a into DC electric power andoutputs the converted DC electric power from the first DC power outputterminal 712 a.

The second power conversion circuit 710 b includes a second power inputterminal 711 b to which electric power obtained when the second antenna740 b receives radio waves is input and a second DC power outputterminal 712 b configured to output DC electric power, converts electricpower input to the second power input terminal 711 b into DC electricpower, and outputs the converted DC electric power from the second DCpower output terminal 712 b.

The control circuit 720 includes a first input terminal 721 connected tothe first DC power output terminal 712 a of the first power conversioncircuit 710 a, a second input terminal 725 connected to the second DCpower output terminal 712 b of the second power conversion circuit 710b, an output terminal 722 connected to the switch 130 and configured tocontrol a connection state of the switch 130, and a power supplyterminal 723.

The power supply terminal 723 of the control circuit 720 is connected tothe power supply 50. The load 60 is connected to the power supply 50 viathe switch 130.

The control circuit 720 switches a connection state of the switch 130 inaccordance with the result of comparing the electric power input to thefirst input terminal 721 with the electric power input to the secondinput terminal 725.

FIG. 20 is a diagram illustrating a case in which the first antenna 740a receives radio waves having an intensity higher than that of thesecond antenna 740 b in an example of the constitution of the latchsystem 100 in the fourth embodiment. A constituent element in this casethat is the same as the latch module 1 m described above will be denotedby the same reference symbol and a description thereof will be omitted.

In this example, a transmission point T2 is located in a near field ofthe first antenna 740 a. In the near field, a change in electric fieldintensity and magnetic field intensity depending on a distance is large.Thus, the electric power due to the radio waves received by the firstantenna 740 a is significantly different from the electric power due tothe radio waves received by the second antenna 740 b.

For example, if radio waves are transmitted in the vicinity of the firstantenna 740 a, an electric field intensity and a magnetic fieldintensity in the vicinity of the second antenna 740 b are significantlyattenuated with respect to an electric field intensity and a magneticfield intensity in the vicinity of the first antenna 740 a.

When the transmission point T2 is located in the near field of the firstantenna 740 a, the electric power due to the radio waves received by thefirst antenna 740 a is significantly different from the electric powerdue to the radio waves received by the second antenna 740 b. Thus, theDC electric power output by the first power conversion circuit 710 a issignificantly different from the DC electric power output by the secondpower conversion circuit 710 b. That is to say, the electric power inputto the first input terminal 721 of the control circuit 720 issignificantly different from the electric power input to the secondinput terminal 725.

The control circuit 720 switches a connection state of the switch 130 inaccordance with the result of comparing the electric powers input to thefirst input terminal 721 and the second input terminal 725. Thus, whenthe transmission point T2 is located in the near field of the firstantenna 740 a, a connection state of the switch 130 is switched.

For example, when the electric power input to the first input terminal721 is electric power which is twice or more the electric power input tothe second input terminal 725, the control circuit 720 controls theswitch 130 to be in a conduction state.

FIG. 21 is a diagram illustrating a case in which the second antenna 740b receives radio waves having an intensity higher than that of the firstantenna 740 a in an example of the constitution of the latch system 100in the fourth embodiment. A constituent element in this case that is thesame as the latch module 1 m described above will be denoted by the samereference symbol and a description thereof will be omitted.

In this example, a transmission point T3 is located in a near field ofthe second antenna 740 b. If radio waves are transmitted from thetransmission point T3 near the second antenna 740 b, an electric fieldintensity and a magnetic field intensity in the vicinity of the firstantenna 740 a are significantly attenuated with respect to an electricfield intensity and a magnetic field intensity in the vicinity of thesecond antenna 740 b.

For example, when the electric power input to the second input terminal725 is larger than the electric power input to the first input terminal721 by a prescribed amount or more, the control circuit 720 controls theswitch 130 to be in a non-conduction state.

As illustrated in FIGS. 20 and 21 , when radio waves in a near field aretransmitted near either the first antenna 740 a or the second antenna740 b, the latch circuit 10 can detect a position of a transmitter andit is possible to switch a connection state of the switch 130 without amalfunction.

FIG. 22 is a diagram illustrating an example of a constitution of thecontrol circuit 720 in the fourth embodiment.

In FIG. 22 , (A) is a diagram illustrating an example of a circuitconstitution of the control circuit 720 of the fourth embodiment. Asillustrated in (A) of FIG. 22 , the control circuit 720 is constitutedof a power detector 726 and a feedback resistor 724. The power detector726 includes a first input terminal 7212, a second input terminal 7252,and the output terminal 7222 as input/output terminals. The powerdetector 726 has the output terminal 7222 connected to the first inputterminal 7212 via the feedback resistor 724. The feedback resistor 724feeds back the electric power of the output terminal 7222 of the powerdetector 726 to an input terminal 7212. For this reason, if the outputterminal 7222 is a high level, the power detector 726 maintains a highlevel of an output terminal 7212 unless a large amount of electric poweris input to the second input terminal 7252 to make the switch 130non-conduction. The power detector 726 includes a current amplifier7261, a current adder 7262, and an current comparator 7263 asconstituent elements. The power detector 726 compares the electricpowers input to the first input terminal 7212 and the second inputterminal 7252 by comparing the currents input as values proportional tothe electric powers input to the first input terminal 7212 and thesecond input terminal 7252.

The current amplifier 7261 amplifies a current I_(INM) input to thesecond input terminal 7252. In this example, the current amplifier 7261amplifies the current input to the second input terminal 7252 G times.

The current adder 7262 adds a current (G×T_(INM)) obtained by amplifyinga current (G×I_(INM)) input to the second input terminal 7252 G timesusing the current amplifier 7261 and a current I_(INP) input to thefirst input terminal 7212. The current adder 7262 outputs the addedcurrent.

The current comparator 7263 compares the current (I_(INP)−G×I_(INM))output as a result of addition by the current adder 7262 with thedetected current I_(DET). The current comparator 7263 outputs a voltagecorresponding to the comparison result to the output terminal 7222.

To be specific, the current comparator 7263 outputs a high level whenthe current output as a result of addition by the current adder 7262 isthe detected current I_(DET) or more and outputs a low level when thecurrent output as a result of addition by the current adder 7262 is lessthan the detected current I_(DET). Hereinafter, the current comparator7263 is also be referred to as a “comparator.”

That is to say, the current comparator 7263 outputs a high level when adifference between a current flowing through the first input terminal7212 and a current obtained by amplifying a current flowing through thesecond input terminal 7252 G times using the current amplifier 7261 isthe detected current I_(DET) or more. Furthermore, the currentcomparator 7263 outputs a low level when a difference between a currentflowing through the first input terminal 7212 and a current obtained byamplifying a current flowing through the second input terminal 7252 Gtimes using the current amplifier 7261 is less than the detected currentI_(DET).

For example, when a gain (an amplification factor) of the currentamplifier 7261 is set to a gain (an amplification factor) which is twicethe gain (the amplification factor), the current comparator 7263 doesnot output a high level unless the current flowing through the firstinput terminal 7212 is a value or more obtained by adding the detectedcurrent I_(DET) to a current obtained by doubling the current flowingthrough the second input terminal 7252.

Hereinafter, a state in which the current comparator 7263 outputs a lowlevel to the output terminal 7222 is also referred to as an “off state”and a state in which the current comparator 7263 outputs a high level tothe output terminal 7222 is also referred to as an “on state.”

In FIG. 22 , (B) is a table showing a correspondence relationshipbetween a current input to the power detector 726 and an outputpotential.

When an current value obtained by subtracting a current obtained byamplifying the current flowing through the second input terminal 7252 Gtimes from the current flowing through the first input terminal 7212 isthe detected current I_(DET) or more, the output terminal 7222 outputs ahigh level. Since the output terminal 7222 is connected to the switch130, in this case, the control circuit 720 controls the switch 130 to bein a conduction state.

When an current value obtained by subtracting the current obtained byamplifying the current flowing through the second input terminal 7252 Gtimes from the current flowing through the first input terminal 7212 isless than the detected current I_(DET), the output terminal 7222 outputsa low level. Since the output terminal 7222 is connected to the switch130, in this case, the control circuit 720 controls the switch 130 to bein a non-conduction state.

FIG. 23 is a diagram illustrating an example of a constitution of thepower detector 726 a having gain (amplification factor) switching in thefourth embodiment. The power detector 726 a is an example of the powerdetector 726. A constituent element in this example that is the same asthe power detector 726 will be denoted by the same reference numeral anda description thereof will be omitted.

An example of a case in which the power detector 726 a switches a gainwill be described with reference to FIG. 23 . As an example, a case inwhich, when the power detector 726 a is in an off state, a gain isdoubled to prevent a malfunction, whereas when the power detector 726 ais in an on state, a gain is set to a gain which is ½ times the gain sothat it is difficult to shift to an off state will be described.

In this example, the power detector 726 a includes a gain switch 7264.

When the second input terminal 7252 of the power detector 726 a isconnected to the current amplifier 7261, the current flowing through thesecond input terminal 7252 can obtain the doubled gain.

When the power detector 726 a is in an off state and receives radiowaves transmitted from a far field, the currents input to the firstinput terminal 7212 and the second input terminal 7252 are substantiallythe same. Thus, a current of the second input terminal 7252 having thedoubled gain becomes larger and a potential of the output terminal 7222is maintain in an off state. That is to say, when the latch module 1 mincludes the power detector 726 a, it is possible to prevent amalfunction.

On the other hand, when the power detector 726 a receives radio waves ina near field to be in an on state, the power detector 726 a can bemaintained in a state by performing setting so that the current I_(INP)flowing through the first input terminal 7212 is larger than the currentI_(INM) flowing through the second input terminal 7252.

For example, if the gain (amplification factor) connected to the secondinput terminal 7252 is changed from 2 times to ½, even if the currentinput to the first input terminal 7212 and the current input to thesecond input terminal 7252 are substantially the same, the currentflowing through the first input terminal 7212 becomes larger. Thus, itbecomes difficult for the power detector 726 a to shift to an off state.That is to say, the latch module 1 m can be easily maintained in the onstate.

FIG. 24 is a diagram illustrating an example of the circuit constitutionof the power detector 726 a having the gain switching in the fourthembodiment. A constituent element in this example that is the same asthe power detector 126 described in the first embodiment will be denotedby the same reference numeral and a description thereof will be omitted.In FIG. 24 , the power detector 726 a further includes a currentamplifier 7261, a current adder 7262, and a gain switch 7264.

The current amplifier 7261 includes a transistor Q5 and a transistor Q6.Both of the transistor Q5 and the transistor Q6 are n-channel typetransistors. The transistor Q5 has a source connected to a ground pointTG, a gate connected to a drain of the transistor Q5 and a gate of thetransistor Q6, and the drain connected to the second input terminal7252. The transistor Q6 has a source connected to the ground point TG,the gate connected to the gate of the transistor Q5, and a drainconnected to the current adder 7262. The transistor Q5 and thetransistor Q6 constitute a current mirror circuit. The current I_(INM)input to the second input terminal 7252 flows between the drain and thesource of the transistor Q5 as a current I1. In this example, ½×I1 flowsbetween the drain and the source of the transistor Q6 as a current I2.

The gain switch 7264 includes a transistor Q7 and a transistor Q8. Thetransistor Q7 is an n-channel type transistor and the transistor Q8 is ap-channel type transistor.

The transistor Q7 has a source connected to the ground point TG, a gateconnected to the gate of the transistor Q6, and a drain connected to adrain of the transistor Q8.

The transistor Q8 has a source connected to a connection point betweenthe drain of the transistor Q6 and the current adder 7262, a gateconnected to the output terminal 7222, and the drain connected to thedrain of the transistor Q7. In this example, 3/2×I1 flows between thedrain and the source of the transistor Q7 as a current I3.

The gain switch 7264 switches a current value of the current flowingthrough the current adder 7262 by controlling the current I3 inaccordance with the state of the output terminal 7222.

When the output terminal 7222 is in a low level, the current I3 flowsbetween the source and the drain of the transistor Q8. In this case,since I2+I3 (that is, ½×I1+3/2×I1=2×I1) flows through the current adder7262, the gain is doubled.

When the output terminal 7222 is in a high level, a current does notflow between the source and the drain of the transistor Q8. In thiscase, since I2 (that is, ½×I1+3/2×I1=2×I1) flows through the currentadder 7262, the gain is halved.

Here, a current flowing between a drain and a source of a MOS transistoris proportional to a gate width W and inversely proportional to a gatelength L.

A value of the gain of the power detector 726 a is arbitrarily adjustedusing the gate width W and the gate length L of the MOS transistorconstituting the transistor Q6 and the transistor Q7.

FIG. 25 is a diagram illustrating an example of a housing 80 with awaterproof structure in the fourth embodiment. As illustrated in FIG. 25, a latch waterproof module 2 c includes a latch circuit 10 p, a powersupply 50 configured to output DC electric power, a load 60 driventhrough DC electric power supplied from the power supply 50, and thehousing 80.

The housing 80 includes the latch circuit 10 p, the power supply 50, andthe load 60 accommodated therein. The housing 80 has waterproofperformance.

Summary of Effects of Fourth Embodiment

According to the embodiment described above, the latch module 1 mincludes the first antenna 740 a and the second antenna 740 b having thesame characteristics and gain as in the first antenna 740 a. The controlcircuit 720 compares the electric power due to the radio waves receivedby the first antenna 740 a with the electric power due to the radiowaves received by the second antenna 740 b.

When a difference between the electric power due to the radio wavesreceived by the first antenna 740 a and the electric power due to theradio waves received by the second antenna 740 b is less than aprescribed value, the transmission point of radio waves is conceivableto be in a far field. Thus, the control circuit 720 does not switch theconnection state of the switch 130. When a difference between theelectric power due to the radio waves received by the first antenna 740a and the electric power due to the radio waves received by the secondantenna 740 b is a prescribed value or more, the transmission point ofradio waves is conceivable to be in a near field. Thus, the controlcircuit 720 switches the connection state of the switch 130.

Therefore, the latch module 1 m can detect that the noise radio wavesfrom the far field is not near the transmitter regardless of theintensity of radio waves and can prevent a malfunction due to the radiowaves from the far field.

Also, since these controls utilize the electric field characteristics ofthe transmission radio waves, power consumption of the battery of thecircuit does not occur for detection.

Furthermore, according to the above-described embodiment, the controlcircuit 720 switches the connection state of the switch 130 to aconduction state when the electric power input from the first inputterminal 721 is larger than the electric power input from the secondinput terminal 725 and switches the connection state of the switch 130to a non-conduction state when the electric power input from the firstinput terminal 721 is smaller than the electric power input from thesecond input terminal 725.

Therefore, when the latch module 1 m includes the control circuit 720,it is possible to switch the power supply 50 and the load 60 between aconduction state and a non-conduction state.

Furthermore, according to the above-described embodiment, the controlcircuit 720 includes the power detector 726. Therefore, the controlcircuit 720 including the power detector 726 can maintain the state ofthe switch 130 with low power consumption.

In addition, according to the above-described embodiment, when the powerdetector 726 includes the current amplifier 7261, in a case in whichthere is a difference between the electric power input to the firstinput terminal 7212 and the electric power input to the second inputterminal 7252, the connection state of the switch 130 is switched.

The connection state of the switch 130 is switched only when adifference of a prescribed value or more set using the gain of thecurrent amplifier 7261 is detected. Thus, the power detector 726 canprevent a malfunction.

Moreover, according to the above-described embodiment, the powerdetector 726 a can switch the gain when including the gain switch 7264.It is possible to switch the gain between when the power detector 726 ais in the on state and when the power detector 726 a is in the offstate.

In a state in which the power detector 726 a is in the off state, whenthe power detector 726 a increases a weight of the gain, the powerdetector 726 a can be easily maintained in the off state and can preventa malfunction.

In a case in which the power detector 726 a is in the on state, when thepower detector 726 a reduces a weight of the gain, the power detector726 a can be easily maintained in the on state.

According to the above-described embodiment, the first antenna 740 a andthe second antenna 740 b are arranged distance from each other at aprescribed distance. The latch module 1 m switches the connection stateof the switch 130 when the transmitter 70 is brought closer to the firstantenna 740 a or the second antenna 740 b.

Therefore, the position in which the transmitter 70 is brought closer tothe antenna to make the connection state of the switch 130 conductive isdifferent from the position in which the transmitter 70 is broughtcloser to the antenna to make the connection state of the switch 130non-conduction. Thus, it is possible to prevent a malfunction.

While the embodiments of the present invention have been described indetail above with reference to the drawings, the specific constitutionis not limited to the embodiments and designs and the like within arange that does not depart from the gist of the present invention arealso included. Furthermore, while the operation has been described froma current according to the electric power using the radio waves receivedby the antennas in the embodiments of the present invention, theoperation may be described from a voltage according to the electricpower using the radio waves received by the antennas.

What is claimed is:
 1. An electronic circuit, comprising: a switch whichis connected between a power supply configured to output direct current(DC) electric power and a load driven by DC electric power supplied fromthe power supply and which switches a connection state between the powersupply and the load from a non-conduction state in which a supply ofelectric power from the power supply to the load is cut off to aconduction state in which the supply of electric power from the powersupply to the load is allowed; a power conversion circuit which includesa power input terminal to which electric power obtained through radiowaves received by an antenna capable of receiving radio waves is inputand a DC power output terminal configured to output DC electric powerand which converts electric power input to the power input terminal intoDC electric power and outputs the converted DC electric power from theDC power output terminal; and a control circuit which includes an inputterminal connected to the DC power output terminal of the powerconversion circuit and an output terminal connected to the switch andconfigured to control a connection state of the switch and controls theconnection state of the switch to be in a conduction state when thepower conversion circuit outputs DC electric power due to receiving theradio waves by the antenna, wherein the power conversion circuitincludes at least a first capacitor including a first electrodeconnected to the power input terminal and a second electrode, a firstdiode having an anode connected to a ground point and a cathodeconnected to the second electrode of the first capacitor, a secondcapacitor including a first electrode connected to the DC power outputterminal and a second electrode connected to a ground point, and asecond diode having an anode connected to the input terminal via acapacitor and a cathode connected to a first electrode of the secondcapacitor, and wherein the power conversion circuit further includes: athird capacitor including a first electrode and a second electrodeconnected to a ground point; a third diode having an anode connected toa second electrode of the first capacitor and a cathode connected to thefirst electrode of the third capacitor; a fourth capacitor including afirst electrode connected to the power input terminal and a secondelectrode; and a fourth diode having an anode connected to a connectionpoint between the first electrode of the third capacitor and the cathodeof the third diode and a cathode connected to the second electrode ofthe fourth capacitor.
 2. The electronic circuit according to claim 1,wherein the power conversion circuit further includes: a fifth capacitorincluding a first electrode and a second electrode connected to a groundpoint; a fifth diode having an anode connected to the second electrodeof the fourth capacitor and a cathode connected to the first electrodeof the fifth capacitor; a sixth capacitor including a first electrodeconnected to the power input terminal and a second electrode; and asixth diode having an anode connected to a connection point between thefirst electrode of the fifth capacitor and the cathode of the fifthdiode and a cathode connected to the second electrode of the sixthcapacitor.
 3. A module, comprising: the electronic circuit according toclaim 2; a power supply configured to output DC electric power; and aload driven through DC electric power supplied from the power supply. 4.The module according to claim 3, wherein the module is accommodated in awaterproof housing.
 5. A system, comprising: the module according toclaim 4; and a transmitter configured to transmit prescribed radio wavesto the module.
 6. A system, comprising: the module according to claim 3;and a transmitter configured to transmit prescribed radio waves to themodule.
 7. A module, comprising: the electronic circuit according toclaim 1; a power supply configured to output DC electric power; and aload driven through DC electric power supplied from the power supply. 8.The module according to claim 7, wherein the module is accommodated in awaterproof housing.
 9. A system, comprising: the module according toclaim 8; and a transmitter configured to transmit prescribed radio wavesto the module.
 10. A system, comprising: the module according to claim7; and a transmitter configured to transmit prescribed radio waves tothe module.